ode:=y(x)*diff(y(x),x)+a*y(x)^2-b*cos(x+c) = 0; 
dsolve(ode,y(x), singsol=all);
 

ode=y[x]*D[y[x],x]+a*y[x]^2-b*Cos[x+c]==0; 
ic={}; 
DSolve[{ode,ic},y[x],x,IncludeSingularSolutions->True]
 

from sympy import * 
x = symbols("x") 
a = symbols("a") 
b = symbols("b") 
c = symbols("c") 
y = Function("y") 
ode = Eq(a*y(x)**2 - b*cos(c + x) + y(x)*Derivative(y(x), x),0) 
ics = {} 
dsolve(ode,func=y(x),ics=ics)
 

\[ \left [ y{\left (x \right )} = \begin {cases} - \sqrt {C_{1} e^{- 2 a x} + i b x e^{- 2 a x - i x} \sin {\left (c + x \right )} + b x e^{- 2 a x - i x} \cos {\left (c + x \right )} + i b e^{- 2 a x - i x} \cos {\left (c + x \right )}} & \text {for}\: a = - \frac {i}{2} \\- \sqrt {C_{1} e^{- 2 a x} - i b x e^{- 2 a x + i x} \sin {\left (c + x \right )} + b x e^{- 2 a x + i x} \cos {\left (c + x \right )} - i b e^{- 2 a x + i x} \cos {\left (c + x \right )}} & \text {for}\: a = \frac {i}{2} \\- \sqrt {\frac {4 C_{1} a^{2}}{4 a^{2} e^{2 a x} + e^{2 a x}} + \frac {C_{1}}{4 a^{2} e^{2 a x} + e^{2 a x}} + \frac {4 a b e^{2 a x} \cos {\left (c + x \right )}}{4 a^{2} e^{2 a x} + e^{2 a x}} + \frac {2 b e^{2 a x} \sin {\left (c + x \right )}}{4 a^{2} e^{2 a x} + e^{2 a x}}} & \text {otherwise} \end {cases}, \ y{\left (x \right )} = \begin {cases} \sqrt {C_{1} e^{- 2 a x} + i b x e^{- 2 a x - i x} \sin {\left (c + x \right )} + b x e^{- 2 a x - i x} \cos {\left (c + x \right )} + i b e^{- 2 a x - i x} \cos {\left (c + x \right )}} & \text {for}\: a = - \frac {i}{2} \\\sqrt {C_{1} e^{- 2 a x} - i b x e^{- 2 a x + i x} \sin {\left (c + x \right )} + b x e^{- 2 a x + i x} \cos {\left (c + x \right )} - i b e^{- 2 a x + i x} \cos {\left (c + x \right )}} & \text {for}\: a = \frac {i}{2} \\\sqrt {\frac {4 C_{1} a^{2}}{4 a^{2} e^{2 a x} + e^{2 a x}} + \frac {C_{1}}{4 a^{2} e^{2 a x} + e^{2 a x}} + \frac {4 a b e^{2 a x} \cos {\left (c + x \right )}}{4 a^{2} e^{2 a x} + e^{2 a x}} + \frac {2 b e^{2 a x} \sin {\left (c + x \right )}}{4 a^{2} e^{2 a x} + e^{2 a x}}} & \text {otherwise} \end {cases}\right ] \]